DE1451142B1 - Condensation device for steam power plants in the sense of a step condenser - Google Patents

Description

The invention relates to a condensation device for steam power plants Precipitation of the steam from working machines with the dissipation of the condensation heat Using a liquid or gaseous coolant, especially air, with at least two individual condensers in the direction of flow of the coolant and in terms of a design of the condenser as Step capacitor are connected in series.

In such condensation systems, efforts are made to keep the condensation at the lowest possible Perform pressure to the gradient to be processed in the prime mover and thus the specific To be able to keep performance as high as possible. However, there are limits to these efforts.

The desire to achieve the lowest possible temperature in order to improve the condensation conditions To make it as cheap as possible, many difficulties oppose the necessary Supply quantities of coolant at low temperature. Construction and operating costs can accordingly sometimes rise very high if a high throughput of cold coolant.

Some improvement in terms of reducing construction costs and operating costs represents the possibility of a series connection of capacitors. Condensation systems have already become known in which two or more Individual capacitors are connected in series in the course of the coolant flow. With such an im The condensation system designed as a step condenser works first from the coolant loaded capacitor with a lower and thus more favorable value compared to a comparable Condensation system in which two condensers are acted upon in parallel by the liquid coolant will. The downstream condenser is naturally due to the increased inlet temperature of the liquid coolant and works accordingly with a higher condensation pressure than with the comparable parallel connection the capacitors.

Nevertheless, viewed overall, there is a slight improvement in the efficiency of the system from about 0.3 to 0.6%. For this, however, there is an additional effort, be it through the production of two partial capacitors instead of a common one, be it through increased pump work to overcome the greater flow resistance of the cooling water flow has become necessary. For these reasons the process of connecting partial capacitors in series did not seem to have any significant advantages to offer so that it did not catch on. Moreover, one had to assume that the amount of coolant must be interpreted in such a way that they are essentially those when they are connected in series if only one capacitor is used.

In a known stage condensation system with air cooling, the total output of the fans is dimensioned as large for the series connection as it is for conventional parallel connections Case is. The experts were therefore of the opinion that the performance of the fan in the transition from the conventional Circuit on the series circuit must be retained.

The invention is based on the object of a condensation device for steam power plants while consciously accepting low efficiency losses of the turbine process, the profitability the plant by reducing the construction costs, the plant and operating costs increase.

This object is achieved in that the condensation stages of an im Compared with conventional condensation systems significantly reduced, especially half

ίο the coolant flow is permeated.

The invention is of particular importance for gas-cooled, especially condensation systems cooled with atmospheric air. Here is due to the low specific heat a very large amount of the coolant required, the corresponding effort of facilities and energy for the promotion. Furthermore, the low heat transfer coefficients lead to very large heat exchangers, which together with the large coolant flow for larger ones Power plants take up an extremely large amount of space.

If, according to the invention, the coolant flow is significantly reduced compared to the known method this is particularly possible with gaseous coolants, since there are no restrictions for these is given in the warm-up, as is often the case with cooling water from biological or other Reasons is the case. Furthermore, the arrangement of the cooling surfaces for the various condensation levels in series connection in the coolant flow in such a way that substantial is possible Space savings compared to known systems can be achieved. This space savings work have a favorable effect on the construction costs and are also beneficial for the overall planning of the power plant essential.

By reducing the amount of coolant compared to the conventional method also significant investment costs by reducing the number of conveyors and by using smaller ones Saved flow channels for the coolant. Finally, the major reduction is the drive power for the conveyors of the coolant to be taken into account, as the reduction in the amount is much more important than that caused by the series connection the cooling surfaces increased flow resistance. It must be mentioned here that only a smaller part of the energy is used for conveying coolant needed for overcoming the pressure loss in the cooling surfaces themselves and the The rest of the energy is consumed for intake, fan, flow and outlet losses. With air cooling the reduction of the coolant flow also leads to the fact that the fan with a better Efficiency can be operated.

According to a further invention, an additional possibility of improving the method is enlargement of the cooling surfaces of the partial capacitors compared to the cooling surface of the conventional single capacitor. This measure has a more favorable thermal effect on the partial capacitors than on Single capacitor, so that there is an economic interest, by increasing the total cooling surface of all partial capacitors to achieve a greater mean vacuum improvement than with the same effort on the individual capacitor would be possible.

The invention is to be described in greater detail on the basis of the drawing

; be explained. The figures show economic (Värmeschaltbildern and diagrams showing the effects. On the other hand, it is more wise the invention. Furthermore, an execution stage condensation, as Fig. 3 shows, Example of the invention illustrated. The same or perfectly reasonable to change the condensation surface Corresponding designations are in the 5 larger, in order in this way to a higher level of suffering Figures with the same reference numerals gain gain than in the case of single-stage condensation. In Fig. 1 is initially a temperature targeting.

) ild illustrated for a condensation process, When using with air or with similar

as it offers cooled condensation systems with gases borrowed from a conventional condensation system with a single-stage capacitor according to FIG. io stage condensation has particular advantages. These } as in FIG. 1 shows the temperature is not only based on a reduction in the cooling) temperature depending on the area of an upper middle amount with increased condensation or surface capacitor. Cooling surfaces, as already explained above, but

Like F i g. 2 shows, the steam flows, which is caused by the 15 location costs also supplied to the condensation turbine 2 with regard to the space required and the instructions 1. This is shown in FIGS. 5 to 7 in more detail, through the exhaust lines 3 to the condensate. In Fig. 5, an embodiment is shown in separator 4. In the condenser 4, the steam is strongly condensed in parts essential for the invention in a pressure p _s , which is illustrated in FIG. 5 in a simplified representation.
: outflowing and at 10 outflowing coolant F i g. 6 shows an exemplary embodiment for the

ron its input temperature t _E on the output 20 associated engine that z. B. as a steam turbine temperature t _A warms up. In Fi g. 1 the cooling surface is designed with three steam outlets. Denotes dementnite F ₁ . The temperature of the condenser - accordingly the condensation system consists of iators i _s is above the temperature of the cooling with an air-cooled three-stage condenser,
ice, which goes from the input value t _E to the output.In the interior of the cooling channel 14, there are three condensate

vert t _A increases. 25 generator stages 15, 16 and 17 are arranged, the steam of which are denoted by 18, 19 and 20 in comparison to this known collector. The lensation system show the F i g. 3 and 4 a condenser stages 15, 16, 17 are essentially a refractive diagram and the corresponding formwork is formed by finned tube elements or the like, interior for a two-stage condensation system after half of which the steam from the machine according to the invention. 30 condensed. As can be seen from FIG. 4, some of the condensate that accumulates is now flowing to the associated collectors 21, 22 and 23. The les exhaust steam through line 8 of the condenser exhaust steam to the condenser stage 9 illustrated in FIG. The con with the different pressures p _v p ₂ and p ₃ to. lensator pressures are now p _sl and p _s2 . Accordingly _{, the condensation temperatures f sl The} ^{condensate collected in the} collectors 21, 22 and 23 is indicated by a md t _S2, not shown in detail. The pressure p _sl and the temperature i _sl let the condensate pump in the feed water circuit be lower than the values of p _s2 and i _S2 . She directs. The cooling air flows in the direction of the arrows 24 are also lower than the values of p _s and t _{s of} the through the cooling duct 14, whereby a through the motor? Ig. 1 and 2. In this way, in the condensate 40 13 driven fan 12 this förlationsstufe 9 increases the amount processed, which is significantly less than if the same amount of steam in each case and thus a condensation surface in a known construction bypass increase compared to the one in FIGS. 1 and 2 arranged one to the other and acted upon by cooling air, known single-stage condensation would be. The pressure loss of the cooling air reached during the run through. 45 flow of the finned tube elements represents the rest of the - In both cases the condensate to be discharged is ^{almost the same as only one part of} the total flow losses iation heat, so that here in advance, which determine the fan output. In this way, the constant amount of coolant used in the whole is required by the power of the fan, the multiple heating of t _A and t _{E is} also almost the same. ^ren series-connected capacitor elements - the hatched areas in FIGS. 1 and 3 50 th is only increased significantly less and the temperature differences and thus the excess heat than is proportional to the increase in the amount of heat in the areas of condensation. From the ^{diagram or the} amount of steam that has been precipitated out, as shown in FIG. 3 it can be seen that the conversation.

iensationsflächeF _{2 is} larger than the corresponding In Fig. 7 is a further embodiment in

Area ^ in Fig. 1. It is therefore a larger con-55 its essential parts for the invention required in Verlensationsfläche than with a single-stage con-simplified representation,
lensation. One could also think of it, the turbine steam is here with two

In the case of single-stage condensation according to FIG. 3, different pressures are fed to the steam collectors 19 or 18 and 2, the condensation surface corresponding to the condensation system. The steam in lohen. In Fig. 1 this is on the right side of the 60, the collector 18 has the lower pressure; Diagram by the dashed lines anchored condenses in the capacitor stage 15. The Konichau light. In this way, however, only a complete amount of densate would collect in the collector 21. A corresponding lowering of the condensation pressure correspondingly condenses the higher pressure vapor with the condensation temperature from the value t _s to collector 19 in the condenser stage 16. The conlen value t _s , reached, since the dashed curve t _E -t _A , 65 densate falls in the collector 22.
laughs _A , flatter and flatter. An enlargement of that of the fans 12, that of the motors 13

ier condensation surface would therefore be driven with a single-stage, conveyed cooling air flows into Condensation hardly bring a profit, which is in the direction of the arrows 24 first through the condensation

Sator stage 15 and then with a correspondingly increased temperature through the capacitor stage 16.

Condensation systems of this type consist of a large number of groups, of which here two are shown, these being arranged next to one another and one behind the other on a stage 25. These The stage is supported by pillars 26, the height of which depends on the size of the facility or on the entire required amount of cooling air is determined.

It is now possible, in the case of the in FIG. 7 when using two-stage condensation get along with about half the amount of cooling air compared to the known single-stage design, so that with the same total cooling surface only half the number of fan units, half the space required in the Floor space and only half the pillar height compared to the single-stage system are required.

However, with this configuration, there occurs a deterioration in the vacuum, so that an amount of cooling air between the full, original and ao of the half and a corresponding enlargement of the Cooling surfaces and the number of fans can represent the economic optimum. So can the optimal Amount of cooling air z. B. be at 60%.

It should also be noted that the invention also applies to condensation systems Injection capacitors, e.g. B. when using the known Heller condensation system, meaning Has. It is possible to use the condensate as an injection condensate of low pressure in a second Inject the condenser at a higher pressure, which means that only half the amount of condensate needs to be circulated and is to be cooled back. Corresponding savings in the own use of the steam power plant and in the construction costs of the same including the cooling tower arise in connection with this Measure.

Claims (4)

Patent claims: 1. Condensation device for steam power plants to precipitate the exhaust steam from Working machines with dissipation of the condensation heat with the help of a liquid or gaseous Coolant, in particular air, with at least two individual condensers in the direction of flow of the coolant and in the sense of a design of the condenser as a step condenser are connected in series, characterized in that the condensation stages of a significantly reduced compared to conventional condensation systems, in particular half the coolant flow are penetrated. 2. Device according to claim 1, characterized by one of gaseous coolant flowed through cooling channel of short length in relation to its cross-section for receiving a fan and two or more condensation stages. 3. Device according to claim 1 or 2, characterized in that the condensation stages overhead distribution pipes, located below Collectors and finned tube elements located between these od. The like. Have. 4. Device according to claim 2 or 3, characterized in that the cooling channel and / or the distributor and collector with increasing exhaust pressure in the direction of the flowing Have coolant flow reduced dimensions. 1 sheet of drawings